tesseract/unittest/baseapi_thread_test.cc

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// (C) Copyright 2017, Google Inc.
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Unit test to run Tesseract instances in parallel threads and verify
// the OCR result.
// Note that success of running this test as-is does NOT verify
// thread-safety. For that, you need to run this binary under TSAN using the
// associated baseapi_thread_test_with_tsan.sh script.
//
// The tests are partitioned by instance to allow running Tesseract/Cube/both
// and by stage to run initialization/recognition/both. See flag descriptions
// for details.
#include <functional>
#include <memory>
#include <string>
#include <tensorflow/core/lib/core/threadpool.h>
#include "absl/strings/ascii.h" // for absl::StripAsciiWhitespace
#include "allheaders.h"
#include "include_gunit.h"
#include <tesseract/baseapi.h>
#include "commandlineflags.h"
#include "log.h"
// Run with Tesseract instances.
BOOL_PARAM_FLAG(test_tesseract, true, "Test tesseract instances");
// Run with Cube instances.
// Note that with TSAN, Cube typically takes much longer to test. Ignoring
// std::string operations using the associated tess_tsan.ignore file when
// testing Cube significantly reduces testing time.
BOOL_PARAM_FLAG(test_cube, true, "Test Cube instances");
// When used with TSAN, having more repetitions can help in finding hidden
// thread-safety violations at the expense of increased testing time.
INT_PARAM_FLAG(reps, 1, "Num of parallel test repetitions to run.");
INT_PARAM_FLAG(max_concurrent_instances, 0,
"Maximum number of instances to run in parallel at any given "
"instant. The number of concurrent instances cannot exceed "
"reps * number_of_langs_tested, which is also the default value.");
namespace tesseract {
static const char* kTessLangs[] = {"eng", "vie", nullptr};
static const char* kTessImages[] = {"HelloGoogle.tif", "viet.tif", nullptr};
static const char* kTessTruthText[] = {"Hello Google", "\x74\x69\xe1\xba\xbf\x6e\x67",
nullptr};
static const char* kCubeLangs[] = {"hin", "ara", nullptr};
static const char* kCubeImages[] = {"raaj.tif", "arabic.tif", nullptr};
static const char* kCubeTruthText[] = {
"\xe0\xa4\xb0\xe0\xa4\xbe\xe0\xa4\x9c",
"\xd8\xa7\xd9\x84\xd8\xb9\xd8\xb1\xd8\xa8\xd9\x8a", nullptr};
class BaseapiThreadTest : public ::testing::Test {
protected:
static void SetUpTestCase() {
CHECK(FLAGS_test_tesseract || FLAGS_test_cube)
<< "Need to test at least one of Tesseract/Cube!";
// Form a list of langs/gt_text/image_files we will work with.
std::vector<std::string> image_files;
if (FLAGS_test_tesseract) {
int i = 0;
while (kTessLangs[i] && kTessTruthText[i] && kTessImages[i]) {
langs_.push_back(kTessLangs[i]);
gt_text_.push_back(kTessTruthText[i]);
image_files.push_back(kTessImages[i]);
++i;
}
LOG(INFO) << "Testing Tesseract on " << i << " languages.";
}
if (FLAGS_test_cube) {
int i = 0;
while (kCubeLangs[i] && kCubeTruthText[i] && kCubeImages[i]) {
langs_.push_back(kCubeLangs[i]);
gt_text_.push_back(kCubeTruthText[i]);
image_files.push_back(kCubeImages[i]);
++i;
}
LOG(INFO) << "Testing Cube on " << i << " languages.";
}
num_langs_ = langs_.size();
// Pre-load the images into an array. We will be making multiple copies of
// an image here if FLAGS_reps > 1 and that is intentional. In this test, we
// wish to not make any assumptions about the thread-safety of Pix objects,
// and so entirely disallow concurrent access of a Pix instance.
const int n = num_langs_ * FLAGS_reps;
for (int i = 0; i < n; ++i) {
std::string path = TESTING_DIR "/" + image_files[i % num_langs_];
Pix* new_pix = pixRead(path.c_str());
QCHECK(new_pix != nullptr) << "Could not read " << path;
pix_.push_back(new_pix);
}
pool_size_ = (FLAGS_max_concurrent_instances < 1)
? num_langs_ * FLAGS_reps
: FLAGS_max_concurrent_instances;
}
static void TearDownTestCase() {
for (auto& pix : pix_) {
pixDestroy(&pix);
}
}
void ResetPool() {
pool_.reset(new tensorflow::thread::ThreadPool(tensorflow::Env::Default(), "tessthread", pool_size_));
}
void WaitForPoolWorkers() { pool_.reset(nullptr); }
std::unique_ptr<tensorflow::thread::ThreadPool> pool_;
static int pool_size_;
static std::vector<Pix*> pix_;
static std::vector<std::string> langs_;
static std::vector<std::string> gt_text_;
static int num_langs_;
};
// static member variable declarations.
int BaseapiThreadTest::pool_size_;
std::vector<Pix*> BaseapiThreadTest::pix_;
std::vector<std::string> BaseapiThreadTest::langs_;
std::vector<std::string> BaseapiThreadTest::gt_text_;
int BaseapiThreadTest::num_langs_;
static void InitTessInstance(TessBaseAPI* tess, const std::string& lang) {
CHECK(tess != nullptr);
EXPECT_EQ(0, tess->Init(TESSDATA_DIR, lang.c_str()));
}
static void GetCleanedText(TessBaseAPI* tess, Pix* pix, std::string* ocr_text) {
tess->SetImage(pix);
char* result = tess->GetUTF8Text();
*ocr_text = result;
delete[] result;
absl::StripAsciiWhitespace(ocr_text);
}
static void VerifyTextResult(TessBaseAPI* tess, Pix* pix, const std::string& lang,
const std::string& expected_text) {
TessBaseAPI* tess_local = nullptr;
if (tess) {
tess_local = tess;
} else {
tess_local = new TessBaseAPI;
InitTessInstance(tess_local, lang);
}
std::string ocr_text;
GetCleanedText(tess_local, pix, &ocr_text);
EXPECT_STREQ(expected_text.c_str(), ocr_text.c_str());
if (tess_local != tess) delete tess_local;
}
// Check that Tesseract/Cube produce the correct results in single-threaded
// operation. If not, it is pointless to run the real multi-threaded tests.
TEST_F(BaseapiThreadTest, TestBasicSanity) {
for (int i = 0; i < num_langs_; ++i) {
TessBaseAPI tess;
InitTessInstance(&tess, langs_[i]);
std::string ocr_text;
GetCleanedText(&tess, pix_[i], &ocr_text);
CHECK(strcmp(gt_text_[i].c_str(), ocr_text.c_str()) == 0)
<< "Failed with lang = " << langs_[i];
}
}
// Test concurrent instance initialization.
TEST_F(BaseapiThreadTest, TestInit) {
const int n = num_langs_ * FLAGS_reps;
ResetPool();
std::vector<TessBaseAPI> tess(n);
for (int i = 0; i < n; ++i) {
pool_->Schedule(std::bind(InitTessInstance, &tess[i], langs_[i % num_langs_]));
}
WaitForPoolWorkers();
}
// Test concurrent recognition.
TEST_F(BaseapiThreadTest, TestRecognition) {
const int n = num_langs_ * FLAGS_reps;
std::vector<TessBaseAPI> tess(n);
// Initialize api instances in a single thread.
for (int i = 0; i < n; ++i) {
InitTessInstance(&tess[i], langs_[i % num_langs_]);
}
ResetPool();
for (int i = 0; i < n; ++i) {
pool_->Schedule(std::bind(VerifyTextResult, &tess[i], pix_[i],
langs_[i % num_langs_], gt_text_[i % num_langs_]));
}
WaitForPoolWorkers();
}
TEST_F(BaseapiThreadTest, TestAll) {
const int n = num_langs_ * FLAGS_reps;
ResetPool();
for (int i = 0; i < n; ++i) {
pool_->Schedule(std::bind(VerifyTextResult, nullptr, pix_[i],
langs_[i % num_langs_], gt_text_[i % num_langs_]));
}
WaitForPoolWorkers();
}
} // namespace